\chapter{TUTORIALS}
Eleven tutorials with illustrations are provided to give the user a
step-by-step walk-through of the basic capabilities of the graphics
editor. Standard login and logout procedures should be followed prior to
beginning and after ending the tutorials.

Tutorial one describes accessing of each of the MGED states.
Tutorials two through six describe the use of
{\bf SOL EDIT}
(solid edit) to alter the shapes of several primitives (solids).
Tutorials seven and eight describe the use of
{\bf OBJ EDIT}
(object edit) to alter the shape of objects (which are made of other objects
and ultimately solids).
Tutorial nine describes the use of
{\bf OBJ PATH}
(object matrix selection) control the extent of the effects of an object edit.
Tutorial ten describes the use of the viewing functions.
Tutorial eleven describes the construction of an object from solids and
other objects.

Each of the tutorials will use the solids contained the MGED database called
``prim.g''.
These can be obtained by making a copy of ``db/prim.g''
from the BRL-CAD Package distribution tree.  It is important to make
a copy of the database and work with that, rather than using the
supplied one.  Changes made during the editing process are written
to the database when they are {\sl accepted}.

The first tutorial shows a sample invocation dialogue.  All other
tutorials start at the first MGED prompt ({\tt mged> }). If the user
wishes to continue from one tutorial to the next without leaving MGED, issue
the {\bf press reset} command before starting each tutorial.
User input will be shown in an
{\em emphasized} font, and MGED output will appear in a {\tt typewriter}
font.  If the user input is shown on the same line as a prompt, the
input is literal.  If the user input is shown on a line by itself,
it is a directive, and is entered in an appropriate fashion.

\section{States Within the Edit Process}

In this tutorial, the user will invoke MGED on a file called ``prim.g'';
attach a {\sl display manager\/}; explore the various MGED states;
and finally, exit MGED.  A MGED database has a treelike structure.  The
leaves are the individual solids, and the other nodes are groupings
of those solids.  The solid editing functions are concerned with defining
and modifying the leaves, and the object editing functions operate
on groups, which are Boolean combinations of solids.  One useful mental
model is to envision solid editing as operating directly on a leaf and
object editing as operating on the arc connecting a pair of nodes.  The
object edit will affect everything below the selected arc (this is why
there is an additional state transition when object editing).

\subsection{Viewing State}

The first task is to invoke MGED.  This tutorial will assume the user
has a copy of the ``prim.g'' database in the current directory.

\noindent
{\tt \$ }{\em mged prim.g}\\
{\tt BRL-CAD Release 3.0 Graphics Editor (MGED) Compilation 82}\\
{\tt Thu Sep 22 08:08:39 EDT 1988}\\
{\tt mike@video.brl.mil:/cad/.mged.4d2}\\

\noindent
{\tt attach (nu|tek|tek4109|ps|plot|sgi)[nu]? }{\em sgi}\\
{\tt ATTACHING sgi (SGI 4d)}\\
{\tt Primitive Objects (units=mm)}\\
{\tt mged> }\\

The first three lines give information about which version of MGED is running,
when it was compiled, and who compiled it.  The next line is the display
manager attach prompt.  This prompt provides a list of available display
managers, then shows what the default will be (selected if the user answers
with a carriage return).  In this case, the Silicon Graphics 4d display
manager was selected, as is noted by the following line.
Next the title of the database and
the unit of measurement used in the database are printed,
and finally, the first prompt is issued.
At this point MGED has loaded ``prim.g''; attached the SGI display;
and is awaiting commands.  Attaching a display also causes what
is known as the MGED {\sl faceplate} to be drawn on the graphics display.

The faceplate has several features of interest.  In the upper left corner
of the display, is a box which always shows the current MGED {\sl state}.
This can be one of six states:  {\bf VIEWING}, {\bf SOL PICK},
{\bf SOL EDIT}, {\bf OBJ PICK}, {\bf OBJ PATH}, or {\bf OBJ EDIT}.

Immediately below, is the menu area.  The only menu item initially shown is
one labeled {\bf BUTTON MENU}.  This menu item toggles the display of the
button menu entries when {\sl selected} (more on selection later).

At the bottom of the display are two status lines.  The first line
contains information about the current view.
The entry labeled {\bf cent=} gives the {\sl model space} coordinates
of the dot in the center of the display.
The entry labeled {\bf sz=} reflects the current size in model units of
the {\sl viewing cube}.  The viewing cube is a mathematical construct
centered on the dot in the center of the display.  The {\bf ang=}
display shows the current rate of rotation in each of the three axes.
The bottom line is used for several kinds of information.
In the {\bf VIEWING} state, it displays the title of the database.

\noindent
{\tt mged>\ }{\em e arb8}\\
{\tt vectorized in 0 sec}\\
{\tt mged>\ }{\em size 12}\\
{\tt mged> }\\

\begin{figure}
\centering \includegraphics{t1-top-vw.ps}
\caption{``arb8'' Top View.}
\label{t1-top-vw}
\end{figure}

The {\bf e} command causes the named object(s) -- a solid named ``arb8''
in this case
-- to be displayed, and the {\bf size} command sets the size of the
viewing cube. Figure \ref{t1-top-vw} shows what the display currently
looks like.  In this view, the X-axis is to the right, the Y-axis points
up, and the Z-axis is perpendicular to (poking out of) the screen.

\noindent
{\em Twist the {\bf Y ROT} knob clockwise and back.}\\
{\em Twist the {\bf X ROT} knob counterclockwise and back.}\\

These knobs, along with the {\bf Z ROT} knob, rotate the viewing cube.
Use of the rotation
knobs allows the user to view the model from any orientation.
Turning a knob clockwise causes a rotation in the positive direction,
while turning a knob counterclockwise causes a negative rotation
(right-hand rule).  The knobs are rate based, not position based;
once a rotation has been started, it will continue until the
knob is returned to zero (or the {\bf zeroknobs} button is pressed).
Rotations are about the viewing cube (screen) axes, not the model axes.
Systems without knobs can use the {\bf knob} command.

\noindent
{\em Move the mouse (or pen) until the cursor is in the {\bf BUTTON MENU}
block and then press the middle mouse button (depress the pen).}\\

\begin{figure}
\centering \includegraphics{t1-rot-vw.ps}
\caption{``arb8'' Rotated View.}
\label{t1-rot-vw}
\end{figure}

Pressing the middle mouse button (or the pen) {\sl selects} something.
When the cursor is inside the menu area, a selection
causes the event described by the menu item to occur.
Selecting {\bf BUTTON MENU} causes the button menu to appear on the left
side of the screen. The {\bf BUTTON MENU} menu item is
a toggle; subsequent selection of this item will cause the button menu
to disappear.
Figure \ref{t1-rot-vw} shows the new display.

\noindent
{\em Move the cursor from the menu area to a point near the
upper left corner of the solid and select it (press the center mouse
button).}\\

In the {\bf VIEWING} state, making a selection while outside of the menu
area will move the selected point to the center of the display.  Look
carefully at the center of the display; the point just selected is now
located at the center dot. Use the {\bf center} command to reset any
translations made with the mouse.

\noindent
{\tt mged> }{\em center 0 0 0}\\
{\tt mged> }\\

From the {\bf VIEWING} state, the user will normally transition to either the
{\bf SOL PICK} or {\bf OBJ PICK} state.
The {\bf SOL PICK} state is selected by:
\begin{itemize}
\item Selecting the {\bf Solid Illum} button menu entry, or,
\item Pressing the {\bf sill} button (this button may be labeled
using some variation of ``Solid Illum''), or,
\item Typing {\bf press sill}.
\end{itemize}
Similar entries ({\bf Object Illum}) and ({\bf oill}) exist for transitioning
into the {\bf OBJ PICK} state.
In general, the {\bf press} command is the basic mechanism (type
{\bf press help} for a list of available commands).  Most of the press
commands have been mapped onto a button box if it is available,
 and some of the
most common are also mapped into the {\bf BUTTON MENU} so they can
accessed without letting go of the mouse.

\subsection{Solid Pick State}

\noindent
{\em Place MGED in the {\bf SOL PICK} state using one of the
above mechanisms.}\\

\begin{figure}
\centering \includegraphics{t1-sol-pk.ps}
\caption{MGED In Solid Pick State.}
\label{t1-sol-pk}
\end{figure}

Upon entering the {\bf SOL PICK} state, the display will look similar to
Figure \ref{t1-sol-pk}.  The {\bf SOL PICK} state used to select which
of the displayed solids is to be edited.  Note that the color of the
solid has changed from red to white.  The screen is divided into as many
horizontal zones as there are solids displayed, and each zone is
assigned to one solid.  As the mouse is moved vertically through each
zone, the corresponding solid is highlighted (``illuminated'') by
drawing it in white.   In this instance, there is only one solid being
displayed, so this state is relatively uninteresting.
If the system being used has no mouse, there is no reason to enter the
{\bf SOL PICK} state.  The user will instead transition directly to
the {\bf SOL EDIT} state using the {\bf sed} command.

\noindent
{\tt mged> }{\em press reject}\\
{\tt mged> }{\em e ellg}\\
{\tt mged> }\\
{\em Press the {\bf sill} button}\\

\begin{figure}
\centering \includegraphics{t1-2s-pk.ps}
\caption{MGED In Solid Pick with Two Solids.}
\label{t1-2s-pk}
\end{figure}

Note that the first action taken was to {\sl reject} the edit.  Any time MGED
is not in the {\bf VIEWING} state, a {\sl reject} command (via
{\bf press}, button, or mouse) discards all editing changes accumulated
since the last transition out of the {\bf VIEWING} state, and places
MGED in the {\bf VIEWING} state.
The display should now look similar to Figure \ref{t1-2s-pk}.
Notice that one solid is white and
the name of that solid is displayed in the upper left corner of the
display, as well as in the bottom status line. The solid to be edited is
selected by moving the mouse up and down until the zone corresponding to
the desired solid is reached. Once the appropriate zone is reached, select it.
This selects a solid, and once a solid is selected,
MGED enters the {\bf SOL EDIT} state.

\subsection{Solid Edit State}

\noindent
{\tt mged> }{\em d ellg}\\
{\tt mged> }\\
{\em Select the solid called ``arb8''.}\\

\begin{figure}
\centering \includegraphics{t1-sol-ed.ps}
\caption{Solid Edit State.}
\label{t1-sol-ed}
\end{figure}

The {\bf d} command removes something from the display.  In this
case, the solid ``ellg'' was removed to reduce clutter.
The display should now look like Figure \ref{t1-sol-ed}.
When MGED enters the solid edit state, the following occurs:
\begin{itemize}
\item The solid selected for editing remains illuminated,
\item The solid is labeled,
\item The coordinates (or dimensions) associated with the labels,
and other information is displayed to the right of the menu area,.
\item If the solid is a member of one or more groups, a similar set
of coordinates called the {\sl PATH} is displayed immediately below
the first set of coordinates,
\item The {\bf *SOLID EDIT*} menu is displayed, and,
\item A solid specific edit menu (in this case the {\bf ARB MENU})
is displayed.
\end{itemize}

The {\bf *SOLID EDIT*} menu provides access to generic operations (translation, rotation
and scaling) common to all solids.
The solid specific edit menu is a list of solid type specific editing operations.
Selecting one of the solid specific edit menus causes a submenu with solid type specific
choices to be displayed.  To remove this submenu, select either the
{\bf RETURN} item in the submenu, or the {\bf edit menu} item in the
{\bf *SOLID EDIT*} menu.

It is in this state that the solid is altered to meet the modeler's
requirements. The shape, positioning, and orientation of the solid is
changed using numeric keyboard input, positioning of the mouse, or by
use of the knobs.  Once the solid has been altered, the edit is
either accepted or rejected.  Accepting the edit causes all changes
made to be written to the database; rejecting the edit ``throws them
away''. Either operation will terminate the edit session and return MGED
to the {\bf VIEWING} state.

\noindent
{\em Reject the edit.}\\

\subsection{Object Pick State}

\noindent
{\em Place MGED in the {\bf OBJ PICK} state.}\\

\begin{figure}
\centering \includegraphics{t1-obj-pk.ps}
\caption{Object Pick State.}
\label{t1-obj-pk}
\end{figure}

Figure \ref{t1-obj-pk} shows what the display looks like when in the
{\bf OBJ PICK} state. As with the {\bf SOL PICK} state, a single solid is
selected.  This solid becomes the reference solid for the object edit.
In the {\bf OBJ PICK} state, the solid will be shown
as a member of one or more objects.  Less obvious is the fact that the
local axes associated with the selected solid are the axes used for the
entire object during the object edit.

\subsection{Object Path State}

\noindent
{\em Select ``arb8''.}\\

\begin{figure}
\centering \includegraphics{t1-obj-ph.ps}
\caption{Object Path Selection State.}
\label{t1-obj-ph}
\end{figure}

MGED transitions into the {\bf OBJ PATH} state once a solid has been
picked from {\bf OBJ PICK}. Figure \ref{t1-obj-ph} is the display in
the {\bf OBJ PATH} state.  When in this state the extent of the editing
operation is set.  Everything below the editing point is affected by the
edit.  The editing point is shown by the {\sl MATRIX} label in the
display.  It is shown as {\bf [MATRIX]} in the upper left part of the
display and as {\bf \_\_MATRIX\_\_} in the second status line.  The editing
point is chosen with the same mechanism used by {\bf SOL PICK} and
{\bf OBJ PICK}.  This time, there is one horizontal zone for each node in
the path between the root and selected leaf.  Moving the mouse up and down
moves the editing point up and down in the tree.  Once again, having a
simple database and only one object in view makes for a relatively
uninteresting situation.

\subsection{Object Edit State}

\noindent
{\em Select the editing point above ``arb8''.}\\

\begin{figure}
\centering \includegraphics{t1-obj-ed.ps}
\caption{Object Edit State.}
\label{t1-obj-ed}
\end{figure}

MGED is now in the {\bf OBJ EDIT} state and the display should look like
Figure \ref{t1-obj-ed}.
When MGED enters the object edit state, the following occurs:
\begin{itemize}
\item The reference solid remains illuminated,
\item The reference solid is labeled,
\item The information associated with the labels is displayed to the right
of the menu area, and
\item The {\bf *OBJ EDIT*} menu is displayed.
\end{itemize}

The {\bf OBJ EDIT} state is used to modify the
Homogeneous Transform Matrix selected during the {\bf OBJ PATH} state.
Permissible operations include uniform and affine scaling of the objects,
as well as translation and rotation.
As with the {\bf SOL EDIT} state, MGED accepts changes entered using
the keyboard, mouse or knobs.

This concludes the first tutorial.  Examples of the appearance of MGED
in each of the six states have been given, along with some idea of what
each of the states is used for.  All that remains is to reject the current
edit, and exit MGED.  Strictly speaking the {\bf q} command could be entered
directly, but doing so, can become a dangerous habit.

\noindent
{\em Select {\bf REJECT Edit} using the mouse.}\\
{\em Press the {\bf reject} button.}\\
{\tt mged> }{\em d arb8}\\
{\tt mged> }{\em q}\\
{\tt \$ }\\
